TY - GEN
T1 - ESTIMATION OF LOAD BEARING CAPACITY IN 3D PRINTED PLA NOTCHED PLATES USING THE THEORY OF CRITICAL DISTANCES
AU - Cicero, Sergio
AU - Arrieta, Sergio
AU - Sanchez, Marcos
N1 - Publisher Copyright:
© 2023 American Society of Mechanical Engineers (ASME). All rights reserved.
PY - 2023
Y1 - 2023
N2 - This paper provides a simple safe approach to obtain estimations of the load-bearing capacity of 3D printed PLA (polylactic acid) plates containing U-notches. The plates are subjected to pure tensile loading and combine different types of notch lengths. The estimations are obtained defining the stress field ahead of the notch tip by the Creager-Paris stress distribution, and establishing the fracture criterion through the Theory of Critical Distances (TCD). This theory requires an additional material parameter, the critical distance (L), to determine failure conditions. Particularly, in fracture evaluations, the TCD provides several failure criteria, among which the Point Method (PM) is particularly simple and has been validated in a number of more conventional materials, such as structural steels, aluminum alloys, different types of polymers and composites. The PM states that fracture occurs when the stress level reaches the inherent strength (σ0) at a distance from the notch tip equal to L/2. L and σ0 are related to each other through the material fracture toughness (Kc), so σ0 is not an additional (second) parameter required for the assessments. In any case, the results obtained in the present work demonstrate the capacity of the proposed methodology for estimating the load-bearing capacity in this specific 3D printed material and for the component geometry and loading conditions analyzed here, which implies low constraint conditions, providing safe reasonably conservative predictions.
AB - This paper provides a simple safe approach to obtain estimations of the load-bearing capacity of 3D printed PLA (polylactic acid) plates containing U-notches. The plates are subjected to pure tensile loading and combine different types of notch lengths. The estimations are obtained defining the stress field ahead of the notch tip by the Creager-Paris stress distribution, and establishing the fracture criterion through the Theory of Critical Distances (TCD). This theory requires an additional material parameter, the critical distance (L), to determine failure conditions. Particularly, in fracture evaluations, the TCD provides several failure criteria, among which the Point Method (PM) is particularly simple and has been validated in a number of more conventional materials, such as structural steels, aluminum alloys, different types of polymers and composites. The PM states that fracture occurs when the stress level reaches the inherent strength (σ0) at a distance from the notch tip equal to L/2. L and σ0 are related to each other through the material fracture toughness (Kc), so σ0 is not an additional (second) parameter required for the assessments. In any case, the results obtained in the present work demonstrate the capacity of the proposed methodology for estimating the load-bearing capacity in this specific 3D printed material and for the component geometry and loading conditions analyzed here, which implies low constraint conditions, providing safe reasonably conservative predictions.
KW - PLA
KW - additive manufacturing
KW - fracture
KW - notch
KW - plate
KW - theory of critical distances
UR - https://www.scopus.com/pages/publications/85179891360
U2 - 10.1115/PVP2023-105581
DO - 10.1115/PVP2023-105581
M3 - Conference contribution
AN - SCOPUS:85179891360
T3 - American Society of Mechanical Engineers, Pressure Vessels and Piping Division (Publication) PVP
BT - Materials and Fabrication
PB - American Society of Mechanical Engineers (ASME)
T2 - ASME 2023 Pressure Vessels and Piping Conference, PVP 2023
Y2 - 16 July 2023 through 21 July 2023
ER -
